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U.S. Department
of Transportation
Aviation Science Activities
for Elementary Grades
Federal Aviation
Administration
Revised 1983
GA-20-30-30
Office of Public Affairs
Aviation Education Programs
Washington, D.C. 20591
1
ACKNOWLEDGMENT
For the compilation of the material in this book and the research required,
the Civil Air Patrol is indebted to the earnest, fair minded teachers who were a
part of the Curriculum Laboratory at the National Aviation Education
Workshop held at Miami University, Oxford, Ohio. From their own experience
they knew the needs of the classrooms and willingly and happily gave of their
experience as well as of their time from school vacations. No one regional need
is recognized above another, for on this small committee alone are represented
the States of Hawaii, Indiana, Ohio, and New York, and the Commonwealth of
Puerto Rico.
The ideas for illustrating the demonstration aids are theirs also, but certain of
the drawings as they appear in the manual are the work of A/2C James E.
Tapp, Headquarters Civil Air Patrol, and to him also is offered here our
appreciation. Appreciation is also due Juanita Hilton for editing and combining
into one book the several basic manuscripts prepared by the committee.
Introduction: FROM TEACHER TO TEACHER
This manual is meant to be a springboard toward your own ideas for
demonstrating concepts of the Air Age to your children, whatever the grade
level. Even little children can learn scientific principles through simple teaching
aids; older pupils can benefit by a review using the same demonstrations. In
some instances, these aids may be set up by the teacher; in others, by the
children as a group project; in still others, by each child with a minimum of
teacher direction.
Many of these suggestions we have used in our own classrooms. All of them
we feel to be of value in illustrating the principles involved. They are not new.
Similar demonstrations and experiments may be found scattered throughout
numerous books, but we have tried to assemble in one manual those we believe
to be most helpful to the teacher in introducing her pupils to natural science.
We do not pretend to cover the field, but trust in the ingenuity of our fellowteachers to enlarge upon our beginnings.
Learn as you teach, and have fun!
The Committee:
Mary Coleman
Ramon Gonzales
Elizabeth Harris
Robert K. Iwamura
Wathen D. Leasor
CONTENTS
Page
Prologue: WHAT IS AN AIRPLANE?
I.
PROPERTIES OF AIR
II.
Air Takes Up Room .............................................................................. 1
Air Has Weight...................................................................................... 3
Air Has Pressure.................................................................................... 3
Air Moves ............................................................................................. 5
Heat Causes Air to Expand.................................................................... 6
Air Contains Moisture ........................................................................... 7
Warm Air Holds More Moisture Than Cold Air..................................... 7
Air Holds Some Things Up.................................................................... 8
Some Things Fly in the Air.................................................................... 9
WHAT MAKES AN AIRPLANE FLY?
III.
Wings.................................................................................................. 11
Propellers ............................................................................................ 13
The Jet Airplane .................................................................................. 14
How Is a Plane Controlled? ................................................................. 14
The Wind Tunnel................................................................................. 16
WEATHER IS IMPORTANT TO AVIATION
General Weather Conditions................................................................ 19
Wind ................................................................................................... 20
Temperature ........................................................................................ 24
Moisture in the Air .............................................................................. 28
Atmospheric Pressure.......................................................................... 31
An airplane is something like a bird—
It has a body;
and a flat tail;
and wings;
and feet.
Prologue: WHAT IS AN AIRPLANE?
It is also something like a fish—
and a dorsal fin;
So when we put the bird parts and the fish
parts together we have an airplane.
Then we give it an engine to make it
go and a pilot to steer it.
I PROPERTIES OF AIR
"What is it that you can touch
But cannot feel;
That has no size or shape
But still is real?"
AIR TAKES UP ROOM
1.
Equipment:
Soda pop bottle
Small funnel
Soda straw
Modeling clay
Cupful of water
Seal the funnel tightly into the neck of the bottle with
modeling clay. Pour the cup of water into the funnel
quickly. The water stays in the funnel because the air in
the bottle cannot get out.
Pass the straw through the funnel into the bottle.
Suck out a mouthful of air. Some of the water goes down
into the bottle, taking the place of the air sucked out.
2.
Equipment:
Wide-necked bottle or jar with an air-tight lid
Soda straw
Modeling clay
Small balloon
Thread
Blow the balloon up just enough to fit very loosely in
the bottle. Tie a thread around the neck of the balloon so
the air will not escape. Drop the balloon into the bottle.
Punch a hole in the lid and insert the straw; seal it with
modeling clay. Screw the lid on the bottle. Suck some of
the air out of the bottle through the straw and clamp your
finger over the top of the straw to prevent air from
rushing back into the bottle. The balloon gets larger
because the air inside the balloon expands as the air
pressure decreases in the bottle.
1
3.
Equipment:
Water glass
Cork
Large glass bowl
Facial tissue
Fill the bowl about three-fourths full of water. Drop
the cork on top of the water. Invert the glass over the
cork and push to the bottom of the bowl. The cork goes
to the bottom of the bowl under the glass. Air in the glass
keeps the water out.
5.
Remove the glass and the cork. Stuff facial tissue into
the bottom of the glass. Invert the glass and push to the
bottom of the bowl. The tissue doesn’t get wet.
4.
Equipment:
2 water glasses
Large dish pan or other container filled
with water
Air, like water, is fluid-you can pour it. Place one
glass into the container so that it fills with water. Place a
second glass into the water upside down so that the air
does not escape. Carefully tilt the air-filled glassunder
the water-filled glass. By doing this, you can pour the air
up in bubbles. Each bubble is a little package of air
made visible by being in the water. With a little practice
you can keep pouring the air back and forth between the
glasses without losing any of it.
2
Equipment:
Soda pop bottle
Pan of water
Put the bottle into the pan so that it fills up with
water. Before the water can get into the bottle, air must
flow out. Watch the air bubbles as they rise to the
surface of the water.
6.
Equipment:
Round balloon
Long balloon
Basketball
Football
Inner tube
Paper bag
Plastic bag
Soap and water
Bubble pipe
Blow up the balloons to the same size, and tie them at
their necks with a piece of string. Tie one balloon to each
end of the dowel stock. Attach another piece of string to
the center of the dowel stock and suspend it from some
convenient place. Balance the dowel stock. Prick one
balloon with a pin. As the air rushes out, the pricked
balloon shoots up and the heavier, air-filled one drops
down.
8.
Equipment:
Football or basketball
Good scale
Squeeze all the air possible out of the ball; then weigh
the ball. Blow the ball up again and weigh it. The
inflated ball should weight a few ounces more.
Blow air into a round balloon and into a long balloon.
Put air into a basketball, a football, and an inner tube.
Blow air into a paper bag. Catch some air in a plastic
bag. Blow soap bubbles.
Air takes up room and assumes the shape of the object
into which it is blown or into which it flows.
AIR HAS WEIGHT
7.
Equipment:
Wooden dowel stock or tinker toy stick
about a foot long
String, 1 yard
2 balloons exactly alike
9.
Equipment:
Wooden upright
Rod about 4 feet long
Pail Sand or gravel
Deflated ball (basketball, volleyball, or
soccerball)
Bicycle pump
Nail the rod at the center to the upright. Suspend
deflated hall at one end and the pail at the other. Using
the sand, balance the two. Inflate the ball, pumping as
much air as the ball will take. Replace it.
The ball pulls down and unbalances the pail of sand,
showing that air does have weight.
AIR HAS PRESSURE
Since moving air particles have weight, they press
with force against whatever they touch. Air presses
upward, downward, sideways-every way. Air presses on
3
all sides of our bodies, but we do not notice it because
our bodies are made to withstand this pressure.
10. Equipment:
Water glass
Piece of thin, fiat cardboard
Fill glass to the top with water. Place the cardboard
over the glass. Carefully turn the glass upside down,
holding cardboard tightly to the glass. Take your hand
away from the cardboard. The cardboard stays in place
against the glass. Tilt the glass or hold it sideways, and
the cardboard still remains in place.
straw with clay. Put the cap on tightly so that no air can
get into the bottle. Now try to suck the water out of the
bottle. No matter how hard you suck, the water will not
flow through the straw. Release the cap on the bottle just
enough to let in some air, and try to suck the water
through the straw. Now, as you suck through the straw,
the air pressure is lowered inside the straw. Air pressing
on the surface of the water in the bottle pushes it up
through the straw as you suck through it.
At A and B the upward and downward pressures
balance, but at C the upward pressure of air is greater
than the downward pressure of water and holds the
cardboard in place.
11. Equipment:
Soda straw or glass tube
Put your finger over the top of a soda straw filled with
water. Lift or tilt it. The water will not run out because
your finger cuts off the air pressure on top, but air still
presses up against the water at the bottom of the straw.
Take your finger away, and the water runs out of the
straw.
12. Equipment:
Bottle or jar with a tight cap Soda straw
Modeling clay
Fill the jar up to the cap with water. Punch a hole in
the cap and insert the soda straw. Seal tightly around the
4
An elephant has a built-in straw, and he puts air
pressure to work every time he takes a drink. He puts his
trunk in water and breathes in to draw the air out of his
trunk. As he does this the water fills his trunk.
13. Equipment:
Large medicine dropper or any kind of a
tube with a suction bulb
Put the dropper or tube in a pan of water and squeeze
the attached bulb, forcing the air out of the tube. Release
the bulb. Water now rushes into the tube. Lift the tube
out of the water. The water does not run out. Air pushes
on the water in the tube and holds it there.
14. Equipment:
2 large, flat, rubber sink-stoppers
16. Put some rather strong perfume on a piece of
cotton. Have the children raise their hands as soon as
they smell it.
Air pressure tug-of-war: After wetting their surfaces,
press the two sink-stoppers together so that no air is
between them. Ask a friend to pull on one while you pull
the other. You can’t pull them apart. But just let the air
get in between the pads or plungers, and presto! they
separate.
15. Equipment:
Tin can with a screw-on metal cap, such as
a maple syrup can
Hotplate or burner
17. Burn a piece of string or a piece of "punk" in a
dish. Notice the direction the smoke travels.
Make sure the can is clean. Pour about an inch of hot
water into the can. Put it on the burner and heat it until
you see the steam coming out of the opening. Wait
another few seconds and turn off the heat. Screw the cap
on tightly and wait for it to cool. The can suddenly
begins to cave in.
18. Notice the trees. Are the leaves moving? Are the
trees bending?
19. Wind is moving air. Create a wind by fanning
yourself with a piece of paper, moving your arms rapidly
back and forth and turning rapidly around the room.
When it was heated water turned into steam, driving
out most of the air. Now as the can cools, the steam
turns back into water, leaving neither air nor steam inside
the can. A partial vacuum has been created.
Consequently, the pressure of air outside the can, being
greater than that inside the can, crushes the can.
AIR MOVES
The air is moving all the time, whether we feel it or
not.
5
20. Hold a sheetof paper at mouth level and blow
hard.
21. Hold a sheet of paper in front of an electric fan.
Fasten some strips of paper to the electric fan.
22. Blow a ping-pong ball across a table top.
23. Equipment:
Card
Cork
Fan
Thumb tack
Soda straw
Pan of water
Make a toy sailboat out of a card, cork, and a thumb
tack. Put it in the sink or in a pan of water. Blow on it.
Blow on it through a straw. Fan it with a fan.
HEAT CAUSES AIR TO EXPAND
25. Equipment:
Balloon
Thread
Iced water or snow
Blow up a balloon. Tie the end tightly to prevent air
from escaping. Hold the balloon over a hot radiator or
other source of heat. Heat will cause the air in the
balloon to expand. Put the balloon on snow or in a dish
of iced water. Cold will cause the air in the balloon to
contract.
26. Equipment:
Balloon
Bottle or water glass
Candle or pan of hot water
24. Equipment:
Paper, 6 inches square
Pin
Pencil with eraser
Make a simple pinwheel. Draw diagonal lines across
the 6-inch square of paper. Cut along the lines to a point
about one-half inch from the center of the square. Bring
alternate points together so that they overlap in the center.
Push a pin through the points of the paper and the center
of the square and then into the eraser on the end of a
pencil (A stick rather than a pencil may be used.)
Blow on it; walk with it; run with it, holding it at
different angles as you run. Hold it near the blower of a
ventilating system or in front of an electric fan.
6
Put a balloon over the mouth of an empty bottle or
glass. Heat the air in the bottle over a lighted candle, a
pan of hot water, or a hot radiator. The heated air
expands and further inflates the balloon.
27. Equipment:
Balloon
Water glass
Pan of hot water
Scissors
Cut the neck of a balloon. Heat an empty glass in a
pan of hot water. Slip the opening of the balloon over the
mouth of the glass. Let the glass cool. The cool air
contracts and sucks the balloon into the glass.
30. Equipment:
Ordinary thermometer
Find the temperature of the air near the ceiling and
near the floor. Compare the readings and discuss why the
warmest air is near the ceiling.
31. Equipment:
Strips of paper
Thumb tacks or scotch tape
Open a window at the top and at the bottom. Fasten
strips of paper so that they will hang in the openings and
be moved by the air currents. Notice where the air is
moving into the room and where it is moving out. The air
coming in at the bottom of the window is cooler than the
air in the room. It forces the warm air to rise.
AIR CONTAINS MOISTURE
28. Equipment:
Bubble pipe
Soapy water
Blow soap bubbles. Discuss why they float. (The
breath is warm; as the bubbles begin to cool they begin to
settle. Observe what happens when you blow bubbles
over a hot radiator.)
29. Equipment:
Test tube
Cork
Put a cork in a test tube, but not too tightly. Hold the
corked tube over a source of heat. As the air warms and
expands, the cork will pop out.
32. When the children paint pictures, discuss where
the water goes when the pictures dry.
33. Discuss what happens to the water given to
potted plants.
34. Put some water in a shallow dish on the window
sill. Leave it for a few days, then observe. Where did the
water go?
35. Boil a small amount of water in a shallow pan.
Observe what happens. Discuss what happens when
water evaporates. Help the children to understand that
water evaporates from rivers, lakes, streams, and ponds
and that when water evaporates it goes into the air as
water vapor.
WARM AIR HOLDS MORE MOISTURE THAN
COLD AIR
36. Equipment:
2 water glasses
Ice cubes
Fill one glass with warm water. Fill another glass
with water and ice cubes. Water collects on the outside
7
of the glass which has the ice cubes in it. This is because
the cold glass comes in contact with the warm, moist air
of the room. Help the children understand why this
happens. (This experiment works better on warm,
moist days in the spring, summer, and fall than in
artificially heated rooms in the winter.)
A balloon filled with a gas lighter than air rises and
floats in the air.
37. Equipment:
Teakettle with a spout
Hot plate or burner
Large strainer
2 trays of ice cubes
Medium-sized pan with handle
Boil water in the teakettle until steam comes from the
spout. Notice that the steam disappears into the air
almost immediately. Fill the strainer full of ice cubes and
hold it near the spout of the teakettle so the steam will go
through it. Clouds form as the steam cools. Help the
children understand why.
Fill the pan with ice cubes and hold it where the steam
from the teakettle will hit the sides ofthe pan. When the
hot vapor or steam hits the sides of the pan, little drops of
water gather on the outside of the pan and drip like rain.
AIR HOLDS SOME THINGS UP
The force of gravity acts constantly upon objects,
causing them to fall toward the earth. Objects rise only
when the force of the air upward is greater than the force
of gravity downward.
Leaves float in the air.
Some seeds are carried by the wind.
8
A blimp is a kind of balloon filled with a gas which is
lighter than air.
38. Equipment:
Silk handkerchief
Small ball or doll
String
Make a parachute with a silk handkerchief, some
string, and a small ball or a small doll. Tie about ten
inches of string to each corner of the handkerchief.
Fasten each piece of string to the ball or the doll. Toss
the parachute into the air, or let the children drop it from
the top of the "monkey bars."
A parachute floats’ downward toward the earth
through the air. When an object falls from a great height
it picks up speed, but the resistance of air finally causes it
to fall at a steady speed called terminal velocity. The
large surface of a parachute acts as an air brake,
checking the velocity of the person or object attached and
making possible a safe landing.
39. Have the children repeat this experiment with
other objects-a feather, a piece of paper, a pencil, a silk
scarf, a piece of cotton cloth, a kite, etc. Take the objects
outside on a windy day and try them out.
40. Equipment:
1 stick, V4" x Y8" x 24"
1 stick, V4" x Y8" x 24"
Paper, strong, 16" x 24"
Glue
Long, narrow strip of cloth
String
If you release the kite string, the kite will fall to the
earth. It falls because the angle at which the surface of
the kite has been held toward the wind has been changed.
The lift upward caused by the angle at which the kite
attacked the air is now less than the pull of gravity
downward.
SOME THINGS FLY IN THE AIR
A bat is a mammal that flies in the air.
A bird is a fowl that flies in the air.
A butterfly is an insect that flies in the air.
An airplane is a machine that flies in the air.
41. Equipment:
Toy airplane with rubber band motor
Balsa glider
The forces acting on a kite:
Wind pressure beneath the kite tends to
hold it up.
Compare a toy airplane having a rubber band motor
with a balsa glider. Let the children fly them. The toy
airplane has wings like a big airplane. It has a propeller
and a motor. The rubber band is the motor. You turn the
propeller to wind up the rubber band. When you let go
the rubber band unwinds and turns the propeller. The
propeller pulls the toy airplane through the air.
The tail keeps the kite upright.
Gravity tends to pull the kite down.
Wind helps a kite fly, unless the kite is being pulled
through the air. A kite should be held at an angle to the
wind which allows the air to strike against the under
surface of the kite in such a manner as to direct the kite
upward as the air striking the kite is deflected downward.
The glider does not have a propeller or a motor.
When you toss the glider into the air, the air pushes up on
the wings. This pressure keeps the glider from coming
straight down.
9
II
WHAT MAKES AN AIRPLANE FLY?
\
WINGS
The force that lifts an airplane and holds it up comes
in part from the air that flows swiftly over and under its
wings.
Hold the strip of paper in your hands and run around
the room.
It doesn’t matter whether you move the air over the
strip of paper by blowing or whether you move the paper
rapidly through the air-either way it rises.
42. Equipment:
Strip of notebook paper or newspaper, about 2 inches
wide and 10 inches long
Book
Paper clips
Make an airfoil (wing) by placing one end of the strip
of paper between the pages of the book so that the other
end hangs over the top of the book as shown in diagram
A. Move the book swiftly through the air, or blow across
the top of the strip of paper. It flutters upward.
Bernoulli’s principle states that an increase in the
velocity of any fluid is always accompanied by a decrease
in pressure. Air is a fluid. If you can cause the air to
move rapidly on one side of a surface, the pressure on
that side of the surface is less than that on its other side.
Hold the book in the breeze of an electric fan so the
air blows over the top of the paper
Take the strip of paper out of the book. Grasp one
end of the paper and set it against your chin, just below
your mouth. Hold it in place with your thumb and blow
over the top of the strip. The paper rises. Try the same
thing after you have fastened a paper clip on the end of
the strip. See how many paper clips you can lift in this
way.
11
Bernoulli’s principle works with an airplane wing. In
motion, air hits the leading edge (front edge) of the wing.
Some of the air moves under the wing, and some of it
goes over the top. The air moving over the top of the
curved wing must travel farther to reach the back of the
wing; consequently it must travel faster than the air
moving under the wing, to reach the trailing edge (back
edge) at the same time. Therefore the air pressure on top
of the wing is less than that on the bottom of the wing.
43. Equipment:
2 sheets of notebook paper
Hold two sheets of notebook paper about four inches
apart. Blow between them. Instead of flying apart they
come together. The air moving rapidly between
45. Equipment:
Ping-pong ball
Tank-type vacuum cleaner
Connect the hose to the blower rather than to the
suction end of the vacuum cleaner. Turn the switch on.
Hold the hose vertically so the stream of air goes straight
the two pieces of paper has less pressure than the air
pressing on the outer sides of the paper.
44. Equipment:
Pin
Spool
Cardboard, 3" x 3", lightweight but firm
Place the pin through the center of the cardboard.
Place the spool over the pin so that the pin goes into the
hole in the spool. Hold the card against the spool and
blow firmly through the spool. Release your hand. The
card does not fall.
12
up. Release the ping-pong ball into the stream of air
about a foot from the nozzle. Slowly tip the nose so that
the air shoots at an angle. The ball will stay suspended
in the airstream. The force of gravity upon the ball tends
to make it drop out of the airstream. However, the fast
moving airstream lessens the air pressure on the portion
of the ball remaining inthe airstream, overcoming the
force of gravity, with the result that the ball remains
suspended.
PROPELLERS
Wings give an airplane lift, but they do not drive it
forward. In some airplanes the propeller (turned by an
engine) drives the plane forward by pushing the air
backward. The air, reacting to the action of the propeller,
pushes it forward. (For every action, there is an equal
and opposite reaction—Newton’s Third Law of Motion.)
As the propeller is attached to the plane, it pulls the plane
through the air.
46. Equipment:
Wagon or roller skate
Small electric fan with long extension cord
48. Equipment for making a balsa wood propeller:
Put a propeller on anything that can move-a wagon or
a roller skate. Use a small electric fan with a very long
extension cord for a propeller. Set it firmly on the roller
skate or wagon. The fan drives the wagon or skate
backwards. This is because the blades are set to throw
the air in front of the fan.
47. Equipment for making a cardboard propeller:
Cardboard, 3 1/2" x 1 1/4"
Soda straw
Cut along the dotted lines as shown in diagram.
Spool
Knife
Strong twine
Small finish nails
Tenpenny nail
Block of balsa or other soft wood
Block of wood, 2" x 2" x 3"
Hacksaw
Nail cutter or large pliers
Drive the tenpenny nail into one end of the wooden
block. Cut off the head of the nail so that the nail is
shorter than the length of the spool. Drive the finish nails
into one end of the spool. Space them evenly between the
hole and the edge of the spool. Carve a propeller from
the balsa wood. Drill two holes in it to match the finish
nails on the spool. Wind the string on the spool and place
the propeller on it, making sure to match the holes to the
finish nails. Pull the string hard and fast.
Carefully and slowly push a pencil point through the
center, turning the pencil as you do so. Make the hole
just barely big enough to push the soda straw through.
Bend the blades at an angle. Spin the straw between your
fingers. Notice where you feel the breeze.
13
The spool and propeller are spun with great speed and
the revolving propeller will fly off, high into the air.
49. A simpler demonstration can be done by twisting
a pencil or chopstick tightly into the hub of the propeller.
Hold the stick between the palms of both hands, propeller
up. Roll it back and forth quickly three or four times and
push it forth into the air. The prop, stick and all, will fly
off into the air and attain good height, demonstrating that
a revolving prop creates thrust.
THE JET AIRPLANE
A jet aircraft has no propeller. Instead it has a
reaction engine in which fuel is burned to expand the air
and build up great pressures. It also has a tailpipe
through which the expanded air and other gases can
escape. The plane is moved forward by the pressure of
the gases inside its engine. Its rate of speed were it in a
vacuum would be the same as that of the escaping gases.
50. You can see how a jet works by an experiment
which uses a toy balloon. Blow up the balloon; pinch the
neck to keep in the air. Let the balloon go. It shoots
across the room. The air inside the balloon is pushing in
all directions to get out. Some of the air escapes through
the open neck, but the air at the opposite end of the
balloon cannot get out, so it pushes the balloon forward.
HOW IS A PLANE CONTROLLED?
A car can go only right or left, but a plane must be
steered up or down as well. It has parts on the wings and
tail called control surfaces to help it. These can be
demonstrated by the use of folded paper gliders and balsa
gliders.
51. Folded paper glider. Use a piece of paper
9" x 6".
The finished glider can be held together at the bottom
with a paper clip. The paper clip can also be used for a
balance. Experiment with the glider, moving the clip up
or back as needed to obtain proper balance.
14
Experiment further by changing the position of the wings
(see 52a. Up and dawn).
52. Control surfaces. Real planes have segments
inserted in wings, in the vertical stabilizer, and in the
horizontal stabilizer. These are called ailerons, rudder,
and elevator. The pilot controls their position from the
airplane cockpit. When he moves them into the airstream, they cause the plane to react to air pressure. By
using them he can go to the right or left and also up and
down.
a. Up and down. Fold the back edges of the paper
glider up, as in the diagram. When you throw the glider,
the tail should go down and the nose should point up. It
may take some practice to get the controls set so the
glider does what you want it to do.
Fold the back edges of the gliderdown. When you
throw the glider, the tail should go up and the nose should
go down. This same thing happens when the pilot tilts
the elevators downward.
b. Right and left. Turn the vertical fin on the glider
a little to the right; the glider will fly toward the right.
The pilot moves his rudder to the right for a right turn,
but he must also bank his plane for the turn, the same as
you would do if you were turning on a bicycle. (You
would lean to the right for a right turn.) The pilot tilts his
plane to one side by using the ailerons. When one tilts up
the other tilts down.
To tilt the plane to the right, the pilot tilts the left
aileron down so the left wing is pushed up. The right
aileron is titled up so the right wing will be pushed down.
You can do the same thing with a paper glider. (This
principle can be illustrated also by suspending the glider
in a wind tunnel.)
When the pilot wants his plane to climb, he moves his
controls so that the elevators tilt up in the same way that
you folded the back edges of the glider. The air hitting
the elevators pushes the tail of the plane down, tilting the
nose upward, so that the plane can climb.
For a left turn, the pilot reverses the process described
above.
15
To Suspend a Paper Glider in a Wind Tunnel:
53. Equipment:
Airplane rubber
Notebook reinforcement rings
Glue
Pill
Purchase airplane rubber (by the yard) at a hobby
shop. Slip one end of the rubber between two notebook
reinforcement rings and glue them together.
54. Equipment:
Balsa glider
A balsa glider may also be used to illustrate the
function of control surfaces. Assemble the glider and
launch it a few times for practice. Make ailerons,
elevators, and a rudder from rather lightweight paper;
glue them to wings and stabilizers. Now, see what you
can do with the glider. With practice you will become
skilled enough to make the glider fly where you want it to
fly.
This kind of glider is excellent to use in a wind tunnel
to illustrate the effects of control surfaces. Remember
what the control surfaces help the plane do:
Fasten this end to the glider as shown in the diagram
below; then anchor with a pin. Even kindergarten
children can use this method of suspending a glider in a
wind tunnel. (See No. 55.)
Climb............The elevators are up.
Glide or dive..The elevators are down.
Right turn......Turn the rudder right.
Right bank.....The right aileron is up; left aileron is
down.
Left turn. .......Turn the rudder left.
Left bank.......Turn the left aileron up; right aileron
down.
THE WIND TUNNEL
A wind tunnel is a tunnel-like chamber through which
air is forced at controlled velocities to study the airflow
about the object suspended within it. Some wind tunnels
are large enough to permit the action of wind pressure on
huge airplanes or missiles to be observed, and in these the
wind velocity may have a force of several thousand miles
per hour. Other wind tunnels are small, with scale
models of airplanes mounted in them.
16
The wind tunnel described below is a simple one for
use with very young children. This type was used very
effectively for six weeks with a kindergarten group. The
children made their own paper gliders and tested them in
the tunnel.
55. Equipment:
Piece of furnace pipe about 4 feet long
Piece of pliofilm, acetate, or some other
transparent material for the tunnel window
Separations from an egg carton
Scotch tape
Corrugated box, the same size as the egg
carton separators
Small electric fan
Bookbinding tape or similar adhesive tape
2 small hooks, the kind used for hanging
cups
Metal shears
With a pair of metal shears, cut a window near one
end of the furnace pipe. Cover the window with the
transparent material, securing it to the pipe with bookbinding tape. Fasten the hooks in the pipe so that when
the glider is suspended from the top hook it can be
observed from the window.
Set the egg carton separators flush against the furnace
pipe, at the end opposite the window. Set the electric fan
inside the box containing the egg car- ton separators.
These separators honeycomb" or straighten the swirling
air currents from the electric fan.
Open the egg carton separators and reinforce the
corners with scotch tape. Open the corrugated box on
both ends and push the flaps inside the box to make the
box stronger. Fit the egg carton separators into one end
of the box. They should fit snugly.
17
III WEATHER IS IMPORTANT TO AVIATION
GENERAL WEATHER CONDITIONS
There are many kinds of weather; weather may vary
from day to day.
56. Keep a weather calendar or weather chart. Use a
large, printed school calendar. Circle each day with color
representing the type of weather, such as orange for
sunny, blue for cloudy, black for rainy.
58. Note the degree of visibility. Is it affected by
haze, fog, rain, or other forms of. precipitation, or is it
clear?
59. Note types of clouds:
cumulus: fluffy, cottony masses; may precede
heavy rains and turbulent winds, forecasting
colder temperatures.
57. Chart the weather for a month, using weather
symbols like the following:
stratus: horizontal layers; may be accompanied
by haze, fog, drizzle, or rain, forecasting
warmer temperatures.
60. Note force of wind (see No. 65). High winds
mean weather changes are coming.
Weather changes may take place rapidly. Record
variations in weather during the day. Try to choose a
windy or very humid day. If a storm rises, note how
quickly it may have risen.
Weather combinations vary. Note types of
precipitation accompanying hot days; cold days. Note
also daily cloud formations and their approximate heights
above the earth.
Weather can often be predicted by observing sky
conditions.
18
61. Make a chemical hygrometer to show the
moisture content of the atmosphere.
Equipment:
Gum arabic ...........½ ounce Small doll with
Cobalt chloride......1 ounce
cotton skirt
Sodium chloride....½ ounce Cardboard
Calcium chloride...75 grains Cotton cloth
Distilled water.......1 ounce
Mix the chemicals into one solution. Dress a small
doll with a skirt of cotton cloth treated with the solution
just mixed. Cut out cardboard rabbits and place on them
large cotton cloth ears treated with this formula. To
treat, dip cloth into solution; let dry.
Keep the jar outdoors to trap rainfall. Place it where
surrounding objects will not interfere with rainfall. After
each storm measure the height in the jar of the
accumulated fall.
Insert funnel through stopper, and stopper into jar
opening. If 4-inch funnel and 2-inch diameter jar are
being used, mark jar height into I-inch intervals. Then
each inch of depth will be equivalent to1A inch of
rainfall. (Note: If jar and funnel are not of these
dimensions, figure markings on jar in proportion.)
64. Keep a detailed weather record.
Cloth will be blue on dry, clear days; lavender on days
when weather is changing; and pink when it is raining or
the humidity is high.
Make a chart like the one which follows and keep a
record for a week. Make observations at the same time
each day.
62. Make clouds.
On a cold or foggy day, let out your breath so that you
can see it.
Boil water in a teakettle. Hold a strainer containing
ice cubes near the spout. See the clouds of steam.
Make a Wilson Cloud Chamber (see No. 97).
63. Measure precipitation (the observable moisture
that comes out of the air).
Equipment:
Tall glass jar, such as an olive jar, 2-inch
diameter preferred
Stopper with I hole, to fit jar
Funnel to fit hole, 4-inch diameter at top
preferred
WIND
Wind Has Force
Many devices depend upon the force of the wind for
their successful operation. Among these are pinwheels,
windmills, gliders, balloons, sailboats, fans, and the like.
65. Make a pinwheel, using sheet of paper 9" x 9"
(See No.’ 24)
Hold the pinwheel in a strong wind or out the window
of a moving car, or make your “wind by running. Wind
will catch the blades of the pinwheel and make it spin.
Wheather Record
Date
Precipitation
Air Temperature
Air pressure
Relative humidity
Wind direction
Wind speed
Sky condition
Type of clouds
19
Holding stapled end, flip wrist rapidly so that the fan
creates a "wind."
Experiment to see whether there is any angle toward
the wind at which you might hold your pinwheel without
it spinning. When does it slow down? Is it when the
plane of the blades is parallel to the wind? Each blade is
an airfoil. Can you explain why? (See No. 42.)
66. Make a windmill
Equipment:
Pinwheel
Small frozen-juice can (dean. empty)
Paper, about 9" x 9"
Scotch or masking tape
Wrap the paper around the can as shown in the
illustration. Fasten it with tape. Insert the pinwheel shaft
through the paper covering near the top. Place the
completed windmill in an open window so the blades will
catch the breeze.
Wind Has Convection Currents
Convection currents are caused when heated air rises
and cold air falls. (Explain why there is better ventilation
in a room when the window is open both at the top and
the bottom.)
68. Equipment:
Stick of punk or cigarette paper
Candle or other source of heat
Ice or other source of cold
Light a stick of punk or, if that is not available, use a
piece of cigarette paper rolled so that it will not burn too
quickly. Hold the smoking punk near hot objects (stove,
radiator, lighted candle, hot brick, lighted electric bulb,
etc.) and watch the path of the smoke. Hold the punk
near cold objects (open refrigerator door, cake of ice, cold
windowpane, cold brick, etc.) and watch the path of the
smoke.
69. To show that heat rises:.
Equipment:
Glass lamp chimney
Candle
Cover glass
Wood splinter
Small sticks
67. Make a fan.
Equipment:
Construction paper, 11" x 8½"
Stapler
Decorate both sides of a piece of construction paper,
11" x 8½". Starting at the short side, fold over and
under, with strips 3A" wide, down length of paper.
Hold one end of the folded paper firmly and staple,
using stapler several times and on both sides if necessary.
20
Light the candle and place the chimney over it, resting
the chimney on sticks so thatair can circulate under the
edge. Put the cover glass over the top of the chimney.
Light the splinter and hold it near the base of the candle
so that smoke will circulate inside the chimney.
Watch the path of the smoke. Remove cover glass
and note changes in the path of the smoke. As warm air
rises, cold air falls to replace it.
70. To show that cold air is heavier than warm air:
Equipment:
2 Quart-size, dry, glass jars
Smoking punk
Sheet of paper
Hot water
Put one jar into refrigerator, the other upside down
under running hot water.
After a few minutes, remove the jar from the
refrigerator. Then let the smoke from punk flow into the
cold jar. Immediately cover the jar mouth with a flat
piece of paper and place the hot jar over it.
73. The force or velocity of the wind is measured by
an instrument called the anemometer. Make a simple
anemometer.
Equipment:
Thin sheets of aluminum
Dowel stock
2 glass beads
2 thin wooden sticks, 18" x ½"
Aluminum solder
The cups of the anemometer are made from the
aluminum. Cut 2 circles about 4" in diameter. Cut these
circles in half along the diagonal. Join the straight edges
with aluminum solder, making 4 small cups.
Attach the cups to 2 crossed sticks, so that all are
heading in the same direction, as illustrated. Join sticks
to dowel stock as follows: Nail, bead, crossed sticks,
bead, dowel stock. Beads will act as bearings so the wind
will turn anemometer freely.
Note that spinning is faster as the force of the wind
Increases.
Remove the paper, and watch the path of smoke
(convection currents). Keep the jars together, but turn
them upside down. Watch the path of smoke as the cold
air descends.
Wind May Vary in Force
The force of wind is measured in terms of the effects it
produces.
71. Using a pinwheel such as described on page 6,
note whether or not its speed increases as that of the wind
striking it increases.
72. Look at the school flag outdoors on the pole. It
may hang limp when wind of little force is present or be
blown about by winds of greater force.
The anemometer may be calibrated with a fair degree
of accuracy as follows: Hold it out the window of an
automobile moving at a constant rate of speed. Note the
speedometer reading and the distance traveled and the
revolutions per minute (rpm) of the anemometer. Drive
the car back along the same road and note the same
readings, being sure the speed of the car and the distance
traveled are the same as before. Average the 2 rpm
counts to allow for the effect of any wind.
Again drive along the same road the same distance,
holding the anemometer out the window of the car, but
this time increase the speed to a steady rate 5 or 10 miles
an hour faster than before. Repeat in the opposite
direction, recording the rpm each time, as was done
before, and average them. On the basis of these counts
make a table of the anemometer rpm's corresponding to
different wind speeds.
21
Wind Has Direction
74. Make a wind vane.
Equipment:
Feather
Straight pin
Soda straw
New lead pencil with firm eraser
Insert a 6"-8" feather in one end of the straw, gluing
lightly, if desired. Find the balance point by holding the
straw on extended finger so it will not tip; insert pin at
this point and stick pin into eraser. Vane will move with
the wind, always pointing in the direction from which the
wind is blowing. Bind the pencil to post outdoors where
vane can swing freely.
Cut arrow and shaft from 20" strip. Cut tailpieces
from 8" strips. Nail them to shaft of arrow on each side;
spread them apart to form an angle of 200 in order to
catch the wind easily, using a protractor to measure the
angle AOB (see illustration). Find the balance point by
resting shaft on extended finger until arrowhead and
tailpieces balance level; drill hole at this point. Insert
long nail in hole. Place bead on nail to act as bearing.
Mount on post, preferably away from buildings.
With compass, determine north. Using the 12" strips,
one marked N and S, and the other E and W, as pointers,
nail the pointers on the post to show direction from which
the wind is blowing. Observe the changes.
76. Make a windsock.
Equipment:
Heavy cloth, about 36" x 24"
4 lengths (about 10" each) of heavy wire
Wire coat hanger
Stick, about 36" long
Large nail
Wooden spool
75. Make a weather vane.
Equipment:
Thin wood strips (white pine good):
1 20" x 4"
2 12" x 1"
2 8"x 3"
Long, slender nail
Small nails
Wooden or glass bead
Post about 10’ high (or exposed corner
of building, such as garage)
Form the hanger into a loop about 9" in diameter.
Attach the 4 wires to this circular loop at 4 equidistant
points on its circumference. Cut cloth into a sleeve (see
diagram above). Sew sides together, making a cone, and
sew larger end of the cone to loop. Bind exposed ends of
wires to the spool. Place the nail through the spool so
that the spool may pivot freely on the nail, and hammer
the nail into the end of the long stick. Place stick
outdoors; nail it to a tall post or to a rooftop away from
obstructions, so that the sock may swing freely with the
wind.
22
The large end of the sock will catch the wind, so that
the small end will point away from the direction from
which the wind is blowing, or will droop if there is not
enough wind to keep it extended.
Observe the position of the sock at different times for
changes in direction and force of the wind.
Windsocks are used chiefly at airports to indicate
wind direction for takeoffs and landings. They help the
pilot select the proper runway.
TEMPERATURE
The atmosphere and the earth receive their warmth
from the sun. This warmth may vary from place to place
and from day to day. The degree of hotness or coldness
of the air around us is called temperature.
Temperature affects our activities, the amount of
clothing we wear, the kind of outdoor exercise we take
and the amount and kind of food and liquid we consume.
A Thermometer Measures Temperature
77. Make a paper thermometer.
Equipment:
Dip about half the length of the ribbon into red ink; let
it dry. Cut from the center of paper a strip 10" long and
the width of the ribbon. Make a cut in the paper V2"
above and another V2" below the space from which the
strip was cut; make these gashes slightly longer than the
width of the ribbon. Insert the ribbon, with the red half
toward the lower end of the paper. Mark the paper in
degrees of temperature to cover the range expected in the
classroom, or wherever the thermometer will be used, to
agree with a real one- say, from 500 to 900. Pull ribbon
up or down to register the proper temperature.
78. Make an air thermometer.
Equipment:
Glass bottle, 1-pint size
Rubber stopper with l hole
Glass tubing to fit hole, 24" long
Water
Dye or colored ink
Sealing wax or paraffin
Scotch or masking tape
Cardboard strip, l0" x 2"
Ordinary thermometer
Place the glass tubing, sealed at one end, through the
stopper. Fill the tube full of water colored with the dye.
Quickly invert the tube, placing the lower end in a bottle
about one-fourth full of the colored water. Press the
stopper firmly in the bottle. Adjust the liquid in the tube
by loosening the stopper or pressing it further into the
bottle until the liquid is about half way along the exposed
portion of the tube above the stopper. Then seal with
wax the tube in the stopper and the stopper in the bottle.
Tape the cardboard to the tube above the stopper.
Still white paper about l 2" x 3"
Narrow white ribbon, about 18" long
Red ink
23
Note the temperature on an accurate thermometer.
Record this temperature on the cardboard, which will act
as a temperature scale. Place the thermometers in a
different temperature situation and leave them for a few
minutes to allow the thermometers to register the new
temperature. Note the new reading and mark on the
scale. Carefully measure the distance between the two
readings on the scale, and mark other degrees of
temperature on it, as all other changes will be in the same
proportion.
Feel an electric light bulb. Switch the electricity on.
See the glow and feel the heat.
Feel a cold steel bar. Place it across a hot flame. See
the red- or white-hot glow and cautiously feel the heat.
The Sun Gives More Heat In Summer Than In Winter
The sun gives more heat in summer because light and
heat rays travel in a straight line from their source.
Temperature Helps Determine the State of the
Weather
Types of precipitation depend on temperature: rain in
warm weather; snow and ice in cold weather.
To find what happens to water when temperature goes
below 32° F:
79. Equipment:
Glass bottle, preferably tall and thin
Screw cap
Water
Masking tape
Fill the bottle to about an inch from the top and mark
level on the outside with masking tape. Put bottle
outdoors in the shade if the day is very cold- below 32°F.
If the day is warmer than 32° F., put the bottle, standing
upright, in the freezing compartment of a refrigerator.
Observe what happens to the level of wateras ice crystals
begin to form in it. Note change in the level when the
water is completely frozen.
82. To show what happens when light rays strike a
surface:
Equipment:
Flashlight
Paper tube, large enough to fit around
flashlight
Large sheet of paper
Table
Lay the paper on a (able. Put the paper tube around
the flashlight. Turn on the flashlight and direct its rays
straight down on the paper. Draw a circle around the
outline of light. Notice brightness of reflected light.
Then hold the flashlight at an angle of about 450
Draw around the light reflected on the paper and notice
its brightness. Compare the area of the circle with that of
the oval.
The Sun Gives Heat
80. Hold one hand in the sunlight and the other in the
shade: feel the difference.
81. Observe that other materials give off heat and
light under certain conditions.
Feel a candlewick, light a candle. See the flame and
feel the heat.
24
83. To show how the angle of the sun’s rays affects
temperature:
Equipment:
2 small boxes filled with sand
2 thermometers
Wooden blocks
Lay a thermometer in each box, with the bulbs lightly
buried in the sand. Then put the boxes in the sun for a
few minutes. Record the temperatures; they should be the
same. Raise one box from the ground by placing small
blocks underneath. Tilt the other by placing blocks under
one edge of the box, so that the sun’s rays fall
perpendicular to the thermometer (i.e., strike the
thermometer at right angle). Leave the boxes in the sun
for a few minutes and then record the temperature.
the preceding experiment, you can conclude that the heat
received varies also.
84. Make a record of thermometer readings inthe
shade at regular intervals during the day. Note that as the
sun’s rays increase the heat around us, the liquid in the
thermometer expands and rises; note that as night
approaches the temperature begins to fall.
85. Place one thermometer in the sun, another in the
shade. Record the readings of each at regular intervals
during the day.
86. The density of the liquid in a thermometer varies
with the temperature around the bulb. Place
thermometers in such places as a dish of ice water,
outdoors on a cool day and on a warm day, indoors on a
very cold day, in the sun, in the shade, over a radiator, in
hot water, in your armpit, in the refrigerator, and near a
glowing electric light bulb.
The Temperature Changes With the Seasons
Seasonal changes in temperature are the result of
changes in the amount of heat received by the earth from
the sun.
Note the position of the winter sun fairly low in the
sky even at midday in temperate zones, accompanied by
long shadows and with little warmth. Compare these
conditions with those of the other seasons (see
Nos. 82, 33).
Shadows change in length and position as the sun
appears to move in an arc across the sky.
87. Make a shadow stick.
Equipment:
3" nail
Board about 10" square
The tilted thermometer records the result of the direct
rays of the sun which represent the direct rays of summer.
The level thermometer records the angular rays of winter.
The tilted thermometer should have a higher reading than
the level thermometer. It is possible to obtain a greater
contrast of angle, and therefore of temperature readings,
when this demonstration is performed in winter.
The Sun’s Heat Varies During the Day
Note that the angle of the sun’s rays varies during the
day, reaching its largest angle at midday. Remembering
25
Put nail in the board centered near one edge. Mark an
S at edge of board in front of the nail. Place the board in
a spot which will have sun all day, being sure that the
edge of the board with the S and the nail are facing south.
Mark along the line of shadow every hour on the hour.
88. Observe your own shadow at different times of
the day and during different days of the season.
89. Observe the shadow of the school flagpole.
90. If a school window sash makes a pattern on the
floor, draw, with chalk, outlines of the pattern on the
floor at intervals of an hour or so, and note the apparent
path of the sunlight.
91. Fun with shadows: make shadow pictures against
a light-colored wall or screen. If there is no sunlight, use
another source of light, such as a bright lamp or a
projector.
92. Note that shadows disappear on a cloudy day.
The Sun Gives Light Day and Night
It is shining all the time on some part of the earth.
When we look at the moon we see reflected sunlight.
26
93. Equipment:
Globe of the world
Flashlight
Point the lighted flashlight in the direction of New
York City on the globe. This side of the globe represents
daylight; the opposite or dark side represents nighttime.
(When it is 12 noon in New York City, it is midnight in
Bangkok, Thailand.) Turn the globe so that the positions
of New York City and Bangkok are reversed. What time
is it in Bangkok? In New York City?
If a globe is not available, mark approximate positions
of these two cities on a basketball, grapefruit, or balloon.
94. Equipment:
5 pieces of cardboard, 8" x 12" (cardboard
inserted in laundered shirts are good)
Cardboard, to make hour and minute hands
Thumbtacks
Masking tape, light colored
Red and black crayon
Draw circle and numerals on each 8" x 12" cardboard
to resemble the face of a clock. Cut out minute and hour
hands, color them, and attach a set to each clock by
means of a thumbtack. Label clocks: New York, New
York; San Francisco, California; Berlin, Germany;
Bangkok, Thailand; and Yokohama, Japan.
Make small signs to show daylight and nighttime,
using the masking tape and lettering the AM and Noon
signs in red crayon and the PM and Midnight signs in
black. (See p. 27)
Set the clocks as follows: New York at 12 noon; San
Francisco, 9 a.m.; Berlin, 6 p.m.; Bangkok, 12 midnight;
and Yokohama, 2 a.m. (the next day). Attach the
masking tape signs above the faces of the clock. Note in
what parts of the world it is daylight and where it is
nighttime. Then move all clocks ahead 3 hours; 6 hours;
12 hours; each time be sure to change the AM and PM
signs.
To make a sling psychrometer, remove the metal
guard from one thermometer and cover its bulb tightly
with the cloth or wick. Nail both the thermometers onto
the board. Using the nut and bolt, attach the spool to the
upper corner of the board, so that it will rotate freely.
Dip the cloth in water. Hold the spool and whirl it
rapidly above your head. Record the temperature
observed on each thermometer. The wet bulb should read
the lower.
From the relative humidity chart, determine the
relative humidity, using the readings of both
thermometers.
MOISTURE IN THE AIR
HOW TO USE CHART:
Humidity
Humidity is the amount of moisture in the air. (See
pp. 7, 8.)
Relative humidity is the amount of moisture in a given
body of air compared with the amount it is capable of
holding at the prevailing pressure and temperature
conditions.
Relative humidity is determined with the help of a wet
and dry bulb thermometer or a slingpsychrometer.
95. Equipment:
2 thermometers, matched for accuracy
Board large enough to hold both thermometers nailed side by side on it
Cotton bag or wick to fit tightly over I bulb
Wooden spool
Long bolt and nut
When wet-and-dry bulb thermometer readings are
known, find intersection of the two solid temperature
lines. At this spot read relative humidity on long- dotted
lines and dew points on short-dotted lines.
For example, if air temperature is 85° and wet bulb
temperature is 75°, their intersection point on the chart
shows the relative humidity to be about 63%, and the dew
point to be about 71°.
To use the sling psychrometer you have made as a
stationary wet and dry bulb thermometer, put a small
bottle containing water under the wet bulb and let a
length of cloth hang down into the bottle so that the cloth
remains wet. When ready to take readings, use the
relative humidity chart as before.
Dew Point
Dew point is the temperature at which the air becomes
saturated with water vapor and the relative humidity
becomes 100 percent.
27
CHART TO DETERMINE
RELATIVE HUMIDITY AND DEW POINT
96. To determine the dew point:
Equipment:
Polished aluminum water glass
Crushed ice or small ice cubes
Room thermometer
Water
Fill the glass one-half full of water at room
temperature, making sure that the glass is dry on the
outside. Put the thermometer into the glass. Add ice
slowly, carefully noting changes in the temperature of the
water and watching for condensation (tiny drops of
water) to occur on the outside of the glass. The
28
temperature at which condensation begins is the dew
point.
Repeat the experiment, using dry ice (CO2) instead of
ice cubes, and note "frost" forming on the outside of the
glass.
Repeat on different days, and record.
Cool air can hold less water vapor than the same
volume of warm air. If saturated air is cooled below the
dew point, condensation occurs.
97. To produce and observe the phenomenon of
condensation of water vapor, make a Wilson Cloud
Chamber.
Equipment:
Carton. about 20" x 20" x 10"
Tall jar with straight sides, such as large
size peanut butter jar
Coffee can, 1-pound size, clean and empty
Piece of thick felt, cut slightly smaller
than the coffee can
Box or block to support the jar
5 pounds of dry ice
Hot water
Large sheet of black construction paper
Filmstrip projector
Masking tape
Cut a hole in the top of the carton into which the jar
exactly fits. Put the dry ice into the carton. Put a
support under the hole and place the jar on it, so that
about an inch of the jar is within the carton. Put masking
tape around the jar so that no air can pass around it, into
or out of the carton.
Place the paper behind the jar and carton so that it can
be seen through the jar. Set up the projector so that the
beam passes through the jar horizontally.
Glue the felt to the underside of the coffee can. Soak
the felt. Fill the coffee can almost full with very hot
water. Place the can on the jar, with the felt pressing on
the jar’s edge. (See diagram.)
Observe condensation: water vapor will form into
clouds, and convection currents will cause them to
circulate within the jar, the cold air rising along its sides
and the warm air descending at its center. When the
vapor clings to particles of dust within the jar, the falling
of ‘brain" is visible. After about 20 minutes, when the
water in the jar has changed to ice at its bottom, it is
possible to see streaks within the jar. These streaks are
cosmic rays.
98. Detecting moisture in the air with a hair
hygrometer:
Equipment:
Empty milk carton
Large sewing needle
Broom straw, 2" long
Scotch or masking tape
Penny
9" human hair wiped clean of oil
4 thumbtacks
Paper clip
Dishpan
Cut the carton so as to make a small horizontal slit
near the top; insert the paper clip. (Fig. l.)
29
Cut a vertical slit near the bottom. Then cut
horizontal slits perpendicular to this cut at its end pointslike an H on its side. (Fig. l.)
Pry out the flaps thus made and bend them to an
upright position. insert the needle through these flaps.
(Fig. 2)
99. Wet your hands. Note that they feel cool while
the water on them is drying (i.e., evaporating).
100. Equipment:
2 glass jars, the same size
Masking tape
Fill 2 clean jars with the same amount of water.
Cover one of the jars tightly. Put the jars in a conspicuous place where they will remain undisturbed. Put a
strip of masking tape at the water-level line of each jar.
Observe them at regular intervals for several days and
again mark the water levels.
The water evaporated mixes with air as water vapor;
it is invisible. The water cycle usually is as follows:
water-vapor, clouds, and rain.
ATMOSPHERIC PRESSURE
The body of air which surrounds the earth is called
atmosphere. Since air itself exerts pressure (pp. 3, 4 &
5), the pressure of the air surrounding the earth is
referred to as atmospheric pressure.
At sea level, air exerts a pressure of 14.7 pounds per
square inch, but a cubic yard of it weighs only about 2
pounds.
101. Atmospheric pressure is measured by a
barometer.
Tie the hair to the paper clip, wind it around the
needle, tape the penny to the other end of the hair, and let
the penny hang over the end of the box, which should be
lying on its side.
Put a card with a scale on the side of the carton under
the straw which has been pushed through the eye of the
needle. (Fig. 3)
Place the hygrometer on a wet towel in a dishpan and
cover with a damp cloth. After 15 minutes remove it
from the cloths and set the straw at numeral 10 on the
scale. Watch to see whether the straw moves.
Since humid air causes the hair to stretch and dry air
causes it to shrink, the straw should move toward the dry
end of the scale as the hair dries.
Evaporation
When water evaporates it becomes vapor, taking heat
from materials around it in the process.
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Equipment:
Small glass or beaker
Glass barometer tube 36" long, closed on
one end
Mercury
Ring stand with clamp
Cardboard strip, 2" x 10"
Scotch or masking tape
Yardstick
Pour the mercury into the barometer tube, filling it
completely. Pour the remaining mercury into a beaker.
Place a finger over the open end of the tube and invert the
tube, lowering it carefully into the beaker containing the
remainder of the mercury. Clamp the tube upright on the
stand.
103. Make a siphon.
Equipment:
Mark a scale of inches and half inches on the cardboard, and label it from 24 to 36 inches. With the
yardstick, measure the actual height of the mercury
column and attach the scale to the proper spot on the
tube.
Watch the day-to-day variations in the height of the
mercury. Record readings of these. Compare them with
radio and newspaper reports of local barometric pressure
conditions.
NOTE:
Be very careful that the mercury
does not come in contact with any jewelry you
may be wearing.
2 identical glass jars
Rubber tubing
Wooden block, 2" thick
Fill one jar with water. Put jars side by side on a
table. Fill tube with water, close one end with your
finger, and lower the other end into the water in the jar
before removing finger. Watch what happens to the level
of water in each jar.
Raise one jar by putting the block under it. Again
watch water levels. The water remains at the same height
in each jar regardless of the difference in height of the
jars, because the atmospheric pressure is the same on the
water surfaces in each jar.
102. The deeper water or air gets, the greater the
pressure becomes.
Equipment:
Large fruit-juice can
Ice pick
Puncture several holes of the same size, at different
levels, in the side of a large fruit-juice can. Notice the
weakness of force with which water escapes from the
upper holes. The ones near the bottom, with the greater
height of water above them, have water shooting out at
some distance.
Watch what happens as the water runs out and the
level of the water lowers. Do all the streams run with
less force than they did at the start?
104. To show that air moves from a high to a low
pressure area:
Equipment:
Heavy glass tube, about 6" long and 1"
in diameter
2 toy balloons of the same size
Place one balloon over one end of the tube. Inflate the
other balloon and, holding the neck of the balloon tightly
to avoid losing air, slip it over the other end of the tube.
Release the neck and observe results.
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Blow through the tube (the manifold pressure
increases) and notice how the straw moves up because
pressure on the small jar increases. If air is sucked out of
the tube, the straw should move down, because the
pressure on the small jar decreases while the pressure
within it remains the same.
Air rushes from the inflated balloon to the empty
balloon. When the air pressures inside the two balloons
become equal, the air stops moving from one to the other.
Are they now the same size?
105. The principles learned about air pressure are put
to work in modern instruments, such as themanifold
pressure gauge used in aircraft. Make a simple manifold
pressure gauge:
Equipment:
Small jar
Rubber from a balloon
Short soda straw
Model airplane glue
Very large jar, with a screw cap
Length of rubber hose
Scotch or masking tape
Cover the small jar tightly with the rubber. Glue soda
straw to it so that one end of the straw is in the center of
the jar’s top. Put the small jar into the larger one. Puncture the lid of the large jar with a nail, forming holes in a
circular pattern the size of tee rubber hose. Punch out
this pattern. Insert the hose in the hole thus formed and,
with tape, seal any space where the hose enters the screw
top.
ž U.S. GOVERNMENT PRINTING OFFICE: 1990-717-000/03879
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